Vented gear spline lubrication

ABSTRACT

A gear box assembly includes an outer housing and a gear box shaft at least partially disposed in the outer housing. The gear box shaft includes an interior region, a reservoir dam that separates the interior region into a reservoir volume and a spline volume and one or more gear box shaft venting holes formed through the gear box shaft near an end thereof. The assembly also includes a regulator disposed at least partially within the gear box shaft, the regulator including one or more regulator vent holes, wherein at least one of the regulator venting holes is in fluid communication with one of the one or more gear box shaft vent holes.

TECHNICAL FIELD

The present disclosure generally relates to lubrication, and more particularly, to a spline lubrication system that includes a vent.

BACKGROUND

Certain mechanical systems include a driving shaft and a driven shaft. The driving shaft may be part of, for example, a gear box and the driven shaft may be part of an accessory of receives rotational energy from the driving shaft. The two shafts may be joined by a spline joint.

A spline joint may include splines (ridges or teeth) on a drive shaft that mesh with grooves in a mating piece and transfer torque to it, maintaining the angular correspondence between them. For instance, the driving shaft may include a male spline on the shaft that matches the female spline on the driven shaft or vice versa.

In operation, the spline joint may need lubrication from time to time.

BRIEF DESCRIPTION

According to one embodiment, a gear box assembly that includes an outer housing and a gear box shaft at least partially disposed in the outer housing is disclosed. The gear box shaft includes an interior region, a reservoir dam that separates the interior region into a reservoir volume and a spline volume and one or more gear box shaft venting holes formed through the gear box shaft near an end thereof. The assembly also includes a regulator disposed at least partially within the gear box shaft, the regulator including one or more regulator vent holes, wherein at least one of the regulator venting holes is in fluid communication with one of the one or more gear box shaft vent holes.

Also disclosed is a power delivery system that includes a driven shaft and a gear box assembly. The gear box assembly includes an outer housing and a gear box shaft at least partially disposed in the outer housing is disclosed. The gear box shaft includes an interior region, a reservoir dam that separates the interior region into a reservoir volume and a spline volume and one or more gear box shaft venting holes formed through the gear box shaft near an end thereof. The assembly also includes a regulator disposed at least partially within the gear box shaft, the regulator including one or more regulator vent holes, wherein at least one of the regulator venting holes is in fluid communication with one of the one or more gear box shaft vent holes.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter which is regarded as the present disclosure is particularly pointed out and distinctly claimed in the claims at the conclusion of the specification. The foregoing and other features, and advantages of the present disclosure are apparent from the following detailed description taken in conjunction with the accompanying drawings in which:

FIGS. 1A and 1B show, respectively, a cross-sectional side view of a gear box driving an accessory and a magnified section thereof;

FIG. 2 is a perspective view of a reservoir according to one embodiment;

FIG. 3 is a partial view of the cross-section of the gear box of FIG. 1 illustrating a lubricant torus formed when a gear box shaft is rotating;

FIG. 4 is a view of the cross-section of the gear box of FIG. 1 illustrating a lubricant pool formed when a gear box shaft initially stops rotating;

FIG. 5 is a view of the cross-section of the gear box of FIG. 1 illustrating the lubricant pool formed after the gear box shaft stops rotating at a time after the lubricant has flowed back through the feed holes;

FIG. 6 is a cross-sectional side view of a gear box driving an accessory illustrating various pressures during operation;

FIG. 7 is a cross-sectional side view of a gear box driving an accessory illustrating various pressures during operation and how lubricant may leak out through the gear box shaft;

FIG. 8 is a cross-sectional side view of a gear box shaft with a regulator according to one embodiment;

FIG. 9 is an exploded perspective view of the regulator of FIG. 8 and the gear box shaft that includes regulator retaining ring;

FIG. 10 is a cut-away side of the a regulator and gear shaft that shows air and lubricant paths; and

FIG. 11 is a cross-section of FIG. 8 taken along line 11-11.

DETAILED DESCRIPTION

Disclosed herein are systems and methods that can lubricate a joint between two shafts and that is resistance to failures in a sealing element (e.g., an o-ring) that seals oil or other lubricants from leaving the system through the joint between the shafts. It shall be understood that while a spline joint is used in the following description, the teachings herein can be applied to any type of connection between two shafts that need to be connected together.

As described above, a spline joint may need lubrication. One manner to provide such lubrication is to utilize a so-called “one shot” lubrication system that provided lubrication every time the connected shafts stop spinning. The inventors hereof have found that such lubrication systems may have limitations when a sealing element fails that result in a loss of lubricant during operation of the system/joint at high altitude. To best understand the inventive nature of the system/method disclosed herein a brief description of an example one shot system is first provided and described in the context of a gear box shaft connected to an accessory shaft in an air craft. The accessory shaft as the term is used herein may refer to an input or output of any element on an aircraft that either generates of receives rotational energy. Examples include, but are not limited to, starters, constant speed drives, generators, hydraulic pump(s), and the hydromechanical engine fuel controls. The gear box shaft may be an input to or an output from a gear box. Depending on the context, either of the accessory or gear box shafts may be referred to as the driving shaft with the other being referred to as the driven shaft. However, for simplicity the following description may describe systems where the gear box shaft is the driving shaft and the accessory shaft is the driven shaft.

FIG. 1A shows a system 100 with a gear box 102 having a gear box (or driving) shaft 104 connected to an accessory (or driven) shaft 106. The gear box 102 may be connected to an aircraft turbine or a ram air fan in one embodiment and may be referred to as an accessory gear box denoting that it provided rotational energy to an accessory. Further, the gear box 102 may define a closed cavity within which some or all of the gear box shaft 104 is housed. An exterior gear 111 is coupled to or integrally formed around an outer surface of the gear box shaft 104 such that it can receive and re-transmit rotational energy received, for example, from the turbine or ram air fan and provide to another element such as accessory 108.

For example, and now referring to the gear box shaft 104 as the driving shaft and the accessory shaft 106 as the driving shaft, the driving shaft 104 is coupled to the driven shaft 106 by a spline joint 110 such that rotational energy is transferred to the driven shaft 106. The particular configuration of the spline joint 110 can be selected from all known configurations of such joints. The spline joint 110 is sealed by a sealing element such as o-ring 112 to prevent a fluid (e.g., lubricant) from escaping an interior region 107 of the driving shaft 104. Such fluid may otherwise be lost to the atmosphere if not sealed. If enough fluid is lost, mechanical errors may occur.

The interior region 107 includes two volumes, a reservoir volume 114 and spline volume 116. The two volumes are separated and defined by a reservoir dam 112. More particularly, the reservoir volume 114 is defined by the torus formed during rotation and having a thickness (e.g., height) as defined by Rh and, similarly, the spline volume 116 is defined by the torus formed during rotation and having a thickness (e.g., height) as defined by Sh. The precise volume and how to determine such is known in the art and may be determined by the skilled artisan. Further, the heights Rh and Sh may be selected (as well as the lengths of the volumes where the length is measured in the axial direction) such that a specific amount of lubricant is delivered to the spline joint 110 each time the system restarted. For example, the height and lengths may be selected such that each time an aircraft takes off a particular amount of lubricant is delivered to the joint 110 as is more fully described below.

The driving shaft 104 is supported by bearings 120 and 121 which allow for the driving shaft 104 to rotate within the gear box 102. It shall be understood that fluid from the interior region 107 of the driving shaft 104 or introduced upstream of the driving shaft 104 may return to an interior region of the gear box 102 through bearing 120 as it may settle in the direction of gravity (shown by arrow g) when the aircraft is not operating (e.g., when the driving shaft is not turning).

The gear box 102 includes a lubrication jet 122 that provide a lubricant into the system (e.g., into shaft 104). The end of the driving shaft 104 opposite the spline joint 110 includes a lubricant regulator (or regulator) 103.

With reference now to FIGS. 1A-1B and 2, details of the regulator 103 are described. The regulator 103 is a generally circular element that includes a perforated base 105 that includes one or more feed holes 130 formed therein. The regulator 103 also includes a tubular sidewall 124. As will be understood from the below, the feed holes 130 are locate a distance Fh from the sidewall 124. At an opposite end of the regulator 103 from the base 105 a lip referred to as a feed dam 126 is provided on the regulator 103. As more fully described below, the length of the sidewall 124 and the height of the feed dam 126 define a feed volume 134. In one embodiment, a regulator retaining ring 132 holds the regulator 103 in place and a regulator sealing ring 120 may also be provided.

During operation (e.g., while an aircraft is running), lubrication jet 122 may direct lubricant towards the regulator 103. Some of this lubricant may enter the interior region 107 as described below. The amount is dependent on the sever factors including Fh, and a distance from an interior wall of the interior region 107 to the top of the feed dam 126 that defines an entry height (shown as Eh).

With reference now to FIGS. 1-3, during operation the lubricant will form a regulator torus 134 and a reservoir torus 140. The feed dam 126 and the sidewall 124 define the volume of the regulator torus 134. The entry height Eh and a length from the base 105 to the reservoir dam 112 defines the volume of the reservoir torus 140. As will be understood, while spinning the distance from a centerline of the driving shaft to an internal diameter of both the regulator torus 134 the reservoir torus 140 and is set by the height of the feed dam 126. Also, the volume of the reservoir torus 140 is depending on the entry height Eh and a distance from the base 105 to the reservoir dam 110.

Stated differently, lubrication is supplied through the feed jet 124 that such that the feed volume 134 fills defining a torus of lubrication (regulator torus 134. Further, the lubricant drains through feed holes 130 into the interior region 107. As discussed above, the reservoir volume 114 fills to the level of feed dam 126 (e.g., Eh) as reservoir torus 140. Any excess lubricant flows back over feed dam 126 into the gear box 102. In this manner, the levels of the regulator torus 134 and a reservoir torus 140 remain constant while the driving shaft 104 is spinning.

With reference now to FIGS. 4 and 5, when the reservoir Torus 140 collapses into chordal volume 150 which is higher than reservoir height Rh. In one embodiment, the feed holes 130 are sized small enough that a majority of the lubricant flows over the reservoir dam 110 into spline volume 116 to form lubrication volume 202. Any remaining lubricant is the reservoir volume not flowing into the spline volume 116 will flow back though the feed holes 130 until the level of the fluid in the reservoir volume is equal to Eh. As illustrated, the amount that remains in the reservoir volume is shown as volume 204. As will be understood, based on the volume the reservoir torus and the spline height Sh, the volume 202 will be at or near the same level on every shut down.

With reference to FIGS. 6 and 7, while the aircraft is operating Pcase is at a first level and the pressure (Pres) in the internal region 105 is lower than Pcase. It has been discovered that if Pcase is substantially higher than Pres a manometer mode may arise causing lubricant to be forced over the reservoir dam 112 from the reservoir volume 114 in the spline volume 116. Such fluid is shown as fluid 160. Such a condition may exist if the o-ring 112 is damaged or missing. In such a case, Pres may approach atmospheric pressure Patm. At high altitudes, the Patm may be enough below Pcase that the manometer effect occurs. Further, this extra oil in the spline volume 116 may escape (see fluid 160) to the atmosphere and not be recovered leading to a constant drain on the lubricant tanks (e.g., the aircraft could lose substantial amounts of lubricant).

One manner in which the pressure difference may be reduced is to vent case pressure into the interior region 107. With reference now to FIGS. 8-11 several views of an alternative regulator 203 are shown that allow for such venting. The regulator 203 of this embodiment allows for the flow of lubricant in the same manner as the regulator 103 described above. To that end, regulator 203 is a generally circular element that includes a perforated base 205 that includes one or more feed holes 230 formed therein. The regulator 203 also includes a tubular sidewall 224. Feed holes 230 are locate a distance Fh from the sidewall 224. The regulator 203 includes a lip referred to as a feed dam 226. As above, the length of the sidewall 224 and the height of the feed dam 226 define a feed volume. In one embodiment, a regulator retaining ring 262 holds the regulator 203 in place and is seated in a groove 280 formed on an inner surface of the shaft 104. The regulator 203 may also include alignment tabs 260 that time the regulator to the driving shaft 104 and are received by slots 270.

According to this embodiment, the driving shaft 104 includes shaft venting holes 250 formed therein. The regulator 203 includes regulator venting holes 290 that corresponding to at least some of the shaft venting holes 250. In the disclosed embodiment, there are four regulator venting holes 290 and correspond to four of the eight shaft venting holes 250. For clarity, an air path (e.g., vent path) is shown by path A and an oil path is show by path B in FIG. 10.

With reference to FIG. 11, where the four regulator venting holes 290 correspond shaft venting holes 250 a direct venting path D is formed and for the remaining four shaft venting holes 250 an indirect venting path ID is formed. The paths D and ID may reduce the difference between the Pcase and Pres such that the manometer effect does not occur, even if o-ring 112 is damaged or missing. While different paths have been shown it shall be understood that only one venting path needs to be formed. As such, the venting path can be formed as long as each of the shaft 102 and the regulator 203 includes one venting hole formed therein. The tabs 260 may ensure that at least one path D is formed.

During operation (e.g., while an aircraft is running), lubrication jet 122 may direct lubricant towards the regulator 203. Some of this lubricant may enter the interior region 107 as described above. The amount is dependent on the sever factors including Fh, and Eh.

While the present disclosure has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the present disclosure is not limited to such disclosed embodiments. Rather, the present disclosure can be modified to incorporate any number of variations, alterations, substitutions or equivalent arrangements not heretofore described, but which are commensurate with the spirit and scope of the present disclosure. Additionally, while various embodiments of the present disclosure have been described, it is to be understood that aspects of the present disclosure may include only some of the described embodiments. Accordingly, the present disclosure is not to be seen as limited by the foregoing description, but is only limited by the scope of the appended claims. 

The invention claimed is:
 1. A power delivery system comprising: a driven shaft; and a gear box assembly comprising: a gear box shaft at least partially disposed in an outer housing and connected by a spline joint to the driven shaft, the gear box shaft comprising: an interior region; a reservoir dam that separates the interior region into a reservoir volume and a spline volume; and one or more gear box shaft venting holes formed through the gear box shaft near an end thereof; and a regulator disposed at least partially within the gear box shaft, the regulator including one or more regulator vent holes, wherein at least one of the regulator venting holes is in fluid communication with one of the one or more gear box shaft vent holes; wherein the one or more gear box shaft venting holes includes four gear shaft venting holes and the one or more regulator venting holes includes four venting holes that are directly aligned with the four gear shaft venting holes; and wherein the regulator includes tabs that mate with slots in gear box shaft that maintaining alignment of the four venting holes with the four gear shaft venting holes.
 2. The power delivery system of claim 1, wherein the regulator further includes: a base; and feed holes formed through the base.
 3. The power delivery system of claim 2, further comprising: a lubrication jet that directs lubricant towards the base of the regulator.
 4. The power delivery system of claim 3, wherein the regulator includes: a tubular sidewall extending from the base; and a feed dam formed on the tubular side wall.
 5. The power delivery system of claim 4, wherein a height of the feed dam and a length of the tubular sidewall define a feed volume.
 6. The power delivery system of claim 3, wherein the base is upstream of the regulator venting holes. 